Confocal surface topography measurement with fixed focal positions

ABSTRACT

An apparatus is described for measuring surface topography of a three-dimensional structure. In many embodiments, the apparatus is configured to focus each of a plurality of light beams to a respective fixed focal position relative to the apparatus. The apparatus measures a characteristic of each of a plurality of returned light beams that are generated by illuminating the three-dimensional structure with the light beams. The characteristic is measured for a plurality of different positions and/or orientations between the apparatus and the three-dimensional structure. Surface topography of the three-dimensional structure is determined based at least in part on the measured characteristic of the returned light beams for the plurality of different positions and/or orientations between the apparatus and the three-dimensional structure.

CROSS-REFERENCE

This application is a continuation application of U.S. patent application Ser. No. 15/906,616, filed Feb. 27, 2018, which is a continuation application of U.S. patent application Ser. No. 15/593,680, filed May 12, 2017, now U.S. Pat. No. 9,939,258, issued Apr. 10, 2018, which is a continuation application of U.S. patent application Ser. No. 14/980,580, filed Dec. 28, 2015, now U.S. Pat. No. 9,675,429, issued Jun. 13, 2017, which is a continuation application of U.S. patent application Ser. No. 14/323,237, filed Jul. 3, 2014, now U.S. Pat. No. 9,261,356, issued Feb. 16, 2016, each of which are incorporated herein by reference in their entirety.

BACKGROUND

A variety of approaches have been developed for measuring surface topography optically. For example, optical systems and methods have been developed and employed that can be used to optically measure surface topography of a patient's teeth. The measured surface topography of the teeth can be used, for example, to design and manufacture a dental prosthesis and/or to determine an orthodontic treatment plan to correct a malocclusion.

One technique for measuring surface topography optically employs laser triangulation to measure distance between a surface of the tooth and an optical distance probe, which is inserted into the oral cavity of the patient. Surface topography measured via laser triangulation, however, may be less accurate than desired due to, for example, sub-optimal reflectivity from the surface of the tooth.

Other techniques for measuring surface topography optically, which are embodied in CEREC-1 and CEREC-2 systems commercially available from Siemens GmbH or Sirona Dental Systems, utilize the light-section method and phase-shift method, respectively. Both systems employ a specially designed hand-held probe to measure the three-dimensional coordinates of a prepared tooth. Both of these approaches, however, require a specific coating (i.e. measurement powder and white-pigments suspension, respectively) to be deposited on the tooth. The thickness of the coating layer should meet specific, difficult to control requirements, which can lead to inaccuracies in the measurement data.

In yet another technique, mapping of teeth surface topography is based on physical scanning of the surface by a probe and by determining the probe's position, e.g., by optical or other remote sensing means.

U.S. Pat. No. 5,372,502 discloses an optical probe for three-dimensional surveying. Various patterns are projected onto the tooth or teeth to be measured and a corresponding plurality of distorted patterns are captured by the optical probe. Each captured pattern can be used to refine the topography measurement.

SUMMARY

Apparatus and methods for measuring surface topography of a three-dimensional structure are provided. In many embodiments, an apparatus for measuring surface topography is configured to illuminate the three-dimensional structure (e.g., a patient's dentition) with light beams for a plurality of different positions and/or orientations between an optical probe of the apparatus and the three-dimensional structure. The apparatus and methods disclosed employ confocal scanning of the three-dimensional structure without optically moving the focal positions of the light beams relative to the optical probe, but instead use movement of the optical probe relative to the structure, thus enabling smaller, faster, and more cost-effective optics.

Thus, in one aspect, an apparatus is described for measuring surface topography of a three-dimensional structure. The apparatus is configured to measure a characteristic of each of a plurality of returned light beams that are generated by illuminating the three-dimensional structure with a plurality of light beams. The characteristic is measured for a plurality of different positions and/or orientations between the apparatus and the three-dimensional structure.

In another aspect, an apparatus is described for measuring surface topography of a three-dimensional structure. In many embodiments, the apparatus includes an optical probe, an optical system, and a processing unit. The optical probe is moved relative to the three-dimensional structure. The optical system focuses each of a plurality of incident light beams to a respective focal position relative to and distal to the optical probe. Returned light beams are generated by illuminating the three-dimensional structure with the incident light beams. The processing unit determines surface topography of the three-dimensional structure based at least in part on a measured characteristic of the returned light beams for a plurality of different relative positions and/or orientations between the optical probe and the three-dimensional structure.

In another aspect, a method is described for measuring surface topology of a three-dimensional structure. The method includes focusing each of a plurality of incident light beams to a respective focal point relative to and distal to an optical probe. Returned light beams are generated by illuminating the three-dimensional structure with the incident light beams. A characteristic of the returned light beams is measured for a plurality of different relative positions and/or orientations between the optical probe and the three-dimensional structure to generate surface topography data for the three-dimensional structure.

Other objects and features of the present invention will become apparent by a review of the specification, claims, and appended figures.

BRIEF DESCRIPTION OF THE DRAWINGS

The novel features of the invention are set forth with particularity in the appended claims. A better understanding of the features and advantages of the present invention will be obtained by reference to the following detailed description that sets forth illustrative embodiments, in which the principles of the invention are utilized, and the accompanying drawings of which:

FIGS. 1A and 1B schematically illustrate, by way of a block diagram, a confocal surface topography measurement apparatus in accordance with many embodiments (FIG. 1B is a continuation of FIG. 1A);

FIG. 2A is a top view of a probing member of a confocal surface topography measurement apparatus, in accordance with an embodiment;

FIG. 2B is a longitudinal cross-section through the probing member of FIG. 2A, depicting exemplary rays passing therethrough;

FIGS. 2C and 2D are end views of the probing member of FIG. 2A, in accordance with many embodiments;

FIG. 3A illustrates an optical probe scanning a structure using fixed focal positions, in accordance with many embodiments;

FIG. 3B shows another view of the optical probe of FIG. 3A during scanning of the structure using fixed focal positions;

FIG. 4A illustrates an optical assembly configured to focus a plurality of light beams to respective focal positions, in accordance with many embodiments;

FIG. 4B illustrates another optical assembly configured to focus a plurality of light beams to a diagonal focal plane, in accordance with many embodiments;

FIG. 5 illustrates a micro lens array for focusing an array of light beams to a diagonal focal plane, in accordance with many embodiments;

FIG. 6A illustrates another optical assembly configured to focus a plurality of light beams to a diagonal focal plane, in accordance with many embodiments;

FIG. 6B illustrates the optical path of returning light beams through the optical assembly of FIG. 6A, in accordance with many embodiments;

FIG. 7A illustrates another optical assembly configured to focus a plurality of light beams to a diagonal focal plane, in accordance with many embodiments;

FIG. 7B illustrates an unfolded configuration of the optical assembly of FIG. 7A; and

FIG. 8 is a simplified block diagram depicting acts of a method for measuring surface topography using fixed focal positions, in accordance with many embodiments.

DETAILED DESCRIPTION

Apparatus and methods are described herein that employ confocal measurement of surface topography. In some approaches, such as those described in U.S. Pat. No. 6,697,164, the disclosure of which is herein incorporated by reference in its entirety, incident light beams generated by a measurement apparatus are used to determine the surface topography of a three-dimensional structure. The apparatus includes an optical probe from which the light beams emanate in order to illuminate the structure. The light beams are focused by focusing optics to respective focal points (also known as focal positions) external to the optical probe. The focal positions are optically scanned through a plurality of positions relative to the optical probe in order to measure the three-dimensional surface topography. The focal positions are moved relative to the optical probe along a direction of propagation of the incident light beams (axial scanning). The focal positions can also be moved orthogonal to the direction of propagation (transverse scanning). Any description herein relating to a direction of light can be regarded as referring to a direction of the principal rays (chief rays) of the light. Similarly, any description herein relating to a direction of propagation of light can be regarded as referring to a direction of propagation of the principal rays of the light. Typically, axial and/or transverse scanning relative to the optical probe is achieved by mechanically moving an optical element, for example via suitable devices, such as galvanometric mirrors, motors, and/or telescopic scanning mechanisms. The use of such axial or transverse scanning components, however, may increase the size, weight, and cost of the measurement apparatus.

In contrast, the apparatus and methods of the present disclosure perform confocal measurement of three-dimensional surface topography without optically moving the position of the focal positions relative to the optical probe. In contrast to the above-described approaches that optically scan the focal positions relative to the optical probe, the approaches described herein focus each light beam to a respective focal point having a fixed spatial disposition relative to the optical probe. Relative movement between the optical probe and the three-dimensional structure is used to move the focal points relative to the structure. Distances between the optical probe and the three-dimensional structure are measured for a plurality of different positions and/or orientations between the optical probe and the three-dimensional structure. The data is then processed in conjunction with data regarding the relative position between the probe and the three-dimensional structure to determine surface topography of the measured structure. By avoiding the use of optical scanning mechanisms, the apparatus and methods disclosed herein may be smaller, faster, and more cost-effective relative to existing optical measurement systems.

In many embodiments, the distance between the optical probe and the three-dimensional structure is determined by measuring one or more characteristics of returning light beams generated by illuminating the structure with the incident light beams. Such characteristics can include, for example, intensity, wavelength, polarization, phase shift, interference, and/or dispersion of the returning light beams. Any description herein relating to light intensity can also be applied to other suitable characteristics of light, and vice-versa. The measurements of the characteristic(s) can be used to detect whether the incident light beams are focused on the surface of the structure and thereby determine the distance between the optical probe and the three-dimensional structure.

For example, the surface topography of the structure can be determined based on measuring the intensities of the returning light beams. In many embodiments, the apparatus is configured such that the intensity of any particular light beam returning from the structure is maximized when the incident light beam is focused on the surface of the structure. By moving the probe relative to the structure, a distance between the probe and the structure for a particular light beam and position and orientation of the probe relative to the structure can be determined by identifying when the intensity of the respective returning reflected light beam is maximized. The surface topography of the structure can then be determined based on the measured intensities of the returned light beams and the position and/or orientation of the optical probe relative to the structure.

As another example, the surface topography can be determined by using spatial frequency analysis to identify which regions of the structure are in focus. In many embodiments, focused regions will contain higher spatial frequencies than out of focus regions. Accordingly, a distance between the probe and a specified region on the structure for a particular position and orientation of the probe relative to the structure can be determined by identifying when the spatial frequencies of the region are maximized. This approach can be applied to determine the surface topography of structures having spatial details.

The apparatus and methods described herein can be used to measure the surface topography of any suitable three-dimensional structure. In many embodiments, optical measurements are taken to generate data representing the three-dimensional surface topography of a patient's dentition. The data can be used, for example, to produce a three-dimensional virtual model of the dentition that can be displayed and manipulated. The three-dimensional virtual models can be used to, for example, define spatial relationships of a patient's dentition that are used to create a dental prosthesis (e.g., a crown or a bridge) for the patient, provide a digital model or a physical model for record keeping purposes, set up a treatment plan, fabricate orthodontic appliances, or any other dental purpose. The surface topography data can be stored and/or transmitted or output, such as to a manufacturing device that can be used to, for example, make a physical model of the patient's dentition that is used by a dental technician to create a dental prosthesis for the patient.

In one aspect, an apparatus is provided for measuring surface topography of a three-dimensional structure. The apparatus can be configured to: (a) focus each of a plurality of light beams to a respective fixed focal position relative to the apparatus; (b) measure a characteristic of each of a plurality of returned light beams that are generated by illuminating the three-dimensional structure with the light beams, the characteristic being measured for a plurality of different positions and/or orientations between the apparatus and the three-dimensional structure; and (c) determine surface topography of the three-dimensional structure based at least in part on the measured characteristic of the returned light beams for the plurality of the different positions and/or orientations between the apparatus and the three-dimensional structure.

In another aspect, an apparatus is provided for measuring surface topography of a three-dimensional structure. The apparatus includes an optical probe configured to be moved relative to the three-dimensional structure. The apparatus includes an illumination unit configured to generate a plurality of incident light beams, each of the incident light beams comprising a first wavelength component. The apparatus includes an optical system configured to focus the first wavelength component of each of the plurality of incident light beams to a respective fixed focal position relative to the optical probe. The apparatus includes a detector unit configured to measure a characteristic of each of a plurality of returned light beams that are generated by illuminating the three-dimensional structure with the incident light beams. The apparatus includes a processing unit coupled with the detector unit and configured to determine surface topography of the three-dimensional structure based at least in part on the measured characteristic of the plurality of returned light beams for a plurality of different relative positions and/or orientations between the optical probe and the three-dimensional structure. In many embodiments, the characteristic is intensity.

In many embodiments, the detector unit includes a two-dimensional array of sensor elements. Each sensor element can be configured to measure the characteristic for a corresponding returned light beam of the plurality of returned light beams. The optical system can be configured to form a two-dimensional pattern of the incident light beams from light generated by the illumination unit, the two-dimensional pattern of incident light beams corresponding to the returned light beams measured by the two-dimensional array of sensor elements. The optical system can include an optics expander unit configured to expand light generated by the illumination unit to form the two-dimensional pattern of the incident light beams. The illumination unit can be configured to produce a two-dimensional pattern of the incident light beams corresponding to the returned light beams measured by the two-dimensional array of sensor elements.

The incident light beams can be focused to a plurality of respective focal lengths relative to the optical probe. In many embodiments, the incident light beams can be arranged in a plurality of rows having a first row and a last row. The incident light beams in each row can be focused to a respective common focal length. The focal lengths of the first row and the last row can be different by a predetermined length. For example, the predetermined length can be from 5 mm to 25 mm. The sensor elements can be arranged in a plane that is oriented for confocal sensing of the returned light beams relative to focal lengths of the first wavelength component of the incident light beams. In some embodiments, the plane of the sensor elements is non-orthogonal to the returned light beams.

In many embodiments, the optical probe is moved through a plurality of different positions and/or orientations relative to the structure. The three-dimensional surface topography can thus be reconstructed from the measured characteristic based at least in part on the position and/or orientation of the optical probe relative to the three-dimensional structure. Any suitable method can be used to determine the relative position and/or orientation between the optical probe and the structure. In many embodiments, the processing unit includes one or more processors and a tangible non-transitory storage device. The tangible non-transitory storage device can store instructions executable by the one or more processors to cause the one or more processors to process data of the measured characteristic generated using the detector unit for the plurality of different relative positions and/or orientations between the optical probe and the three-dimensional structure. The data can be processed by the one or more processors to determine relative position and/or orientation between the optical probe and the three-dimensional structure.

In many embodiments, the apparatus further includes a motion tracking device configured to collect motion data. The processing unit can include one or more processors and a tangible non-transitory storage device. The tangible non-transitory storage device can store instructions executable by the one or more processors to cause the one or more processors to process the motion data to determine relative position and/or orientation between the optical probe and the three-dimensional structure. For example, the motion tracking device can include a camera and the motion data can include image data. In another example, the motion tracking device can include a gyroscope and/or an accelerometer. As a further example, the motion tracking device can include an electromagnetic sensor.

Any suitable configuration of the plurality of incident light beams can be used. For example, the optical system can be configured to focus the first wavelength component of the light beams to at least 10 different focal lengths relative to the scanner, and the focal lengths can have a range of at least 10 mm.

In another aspect, a method is provided for measuring surface topography of a three-dimensional structure. The method can include generating a plurality of incident light beams, each of the incident light beams including a first wavelength component. The first wavelength component of each of the incident light beams can be focused to a respective focal position relative to an optical probe. A characteristic of each of a plurality of returned light beams that are generated by illuminating the three-dimensional structure with the incident light beams can be measured for a plurality of different relative positions and/or orientations between the optical probe and the three-dimensional structure. The measured characteristic for the plurality of different relative positions and/or orientations between the optical probe and the three-dimensional structure can be processed to generate surface topography data for the three-dimensional structure. The surface topography for the three-dimensional structure can be generated using the surface topography data. In many embodiments, the measured characteristic is intensity. In many embodiments, the method includes tracking changes in relative position and/or orientation between the optical probe and the three-dimensional structure.

The incident light beams can be arranged in a plurality of rows having a first row and a last row. For example, the incident light beams in each row can be focused to a respective common focal length. The focal lengths of the first row and the last row can be different by a predetermined length. For example, the predetermined length can be at least 10 mm. The incident light beams can be focused to any suitable respective fixed positions relative to the probe. For example, the wavelength component of the light beams can be focused to at least 10 different focal lengths relative to the scanner, and the focal lengths can have a range of at least 10 mm.

Turning now to the drawings, in which like numbers designate like elements in the various figures, FIGS. 1A and 1B illustrate an apparatus 20 for measuring surface topography optically. The apparatus 20 includes an optical device 22 coupled to a processor 24. The illustrated embodiment is particularly useful for measuring surface topography of a patient's teeth 26. For example, the apparatus 20 can be used to measure surface topography of a portion of the patient's teeth where at least one tooth or portion of tooth is missing to generate surface topography data for subsequent use in design and/or manufacture of prosthesis for the patient (e.g., a crown or a bridge). It should be noted, however, that the invention is not limited to measuring surface topography of teeth, and applies, mutatis mutandis, also to a variety of other applications of imaging of three-dimensional structure of objects (e.g., for the recordal of archeological objects, for imaging of a three-dimensional structure of any suitable item such as a biological tissue, etc.).

The optical device 22 includes, in the illustrated embodiment, a light source (e.g., semiconductor laser unit 28) emitting a light, as represented by arrow 30. The light beam 30 can include a single wavelength component or multiple wavelength components. In some instances, light with multiple wavelength components can be generated by a plurality of light sources. The light passes through a polarizer 32, which causes the light passing through the polarizer 32 to have a certain polarization. The light then enters into an optic expander 34, which increases the diameter of the light beam 30. The light beam 30 then passes through a module 38, which can, for example, be a grating or a micro lens array that splits the parent beam 30 into a plurality of light beams 36, represented here, for ease of illustration, by a single line.

The optical device 22 further includes a partially transparent mirror 40 having a small central aperture. The mirror 40 allows transfer of light from the laser unit 28 through the downstream optics, but reflects light travelling in the opposite direction. It should be noted that in principle, rather than a partially transparent mirror, other optical components with a similar function may be used (e.g., a beam splitter). The aperture in the mirror 40 improves the measurement accuracy of the apparatus. As a result of this mirror structure, the light beams produce a light annulus on the illuminated area of the imaged object as long as the area is not in focus. The annulus becomes a sharply-focused illuminated spot when the light beam is in focus relative to the imaged object. Accordingly, a difference between the measured intensity when out-of-focus and in-focus is larger. Another advantage of a mirror of this kind, as opposed to a beam splitter, is that internal reflections that occur in a beam splitter are avoided, and hence the signal-to-noise ratio is greater.

The optical device 22 further includes focusing optics 42, relay optics 44 and an endoscopic probe member 46. The focusing optics 42 can include suitable optics for focusing the light beams 36 to a plurality of respective focal points at fixed spatial dispositions relative to the probe member 46, as described below. In many embodiments, the focusing optics 42 is static, such that the optical device 22 does not employ mechanisms to scan the focal points (e.g., axially or transversely) relative to the probe member 46. In many embodiments, the relay optics 44 is configured to maintain a certain numerical aperture of the light beam's propagation.

The endoscopic probe member 46 can include a light-transmitting medium, which can be a hollow object defining within it a light transmission path or an object made of a light-transmitting material (e.g., a glass body or tube). The light-transmitting medium may be rigid or flexible (e.g., fiber optics). In many embodiments, the endoscopic probe member 46 includes a mirror of the kind ensuring total internal reflection and directing the incident light beams towards the patient's teeth 26. The endoscope 46 thus emits a plurality of incident light beams 48 impinging on to the surface of the patient's teeth 26.

The endoscope 46 can include one or more motion tracking elements 47 (e.g., a gyroscope, an accelerometer, targets for optical tracking, an electromagnetic sensor). In many embodiments, the motion tracking element 47 generates a motion tracking signal in response to movement of the endoscope 46. In many embodiments, the motion tracking signal is processed by the processor 24 to track changes in spatial disposition of the endoscope 46 in six degrees of freedom (i.e., three translational degrees of freedom and three rotational degrees of freedom).

In many embodiments, the incident light beams 48 form a two-dimensional array of light beams arranged in a plane, relative to a Cartesian reference frame 50, and propagating along the Z-axis. The light beams 48 can be focused to respective focal points defining a suitable focal plane, such as a plane orthogonal to the Z axis (e.g., an X-Y plane) or a non-orthogonal plane. When the incident light beams 48 are incident upon an uneven surface, the resulting array of illuminated spots 52 are displaced from one another along the Z-axis, at different (X_(i),Y_(i)) locations. Thus, while an illuminated spot 52 at one location may be in focus for a given relative spatial disposition between the endoscope 46 and the teeth 26, illuminated spots 52 at other locations may be out-of-focus. Therefore, the light intensity of the returned light beams of the focused spots will be at its peak, while the light intensity at other spots will be off peak. Thus, for each illuminated spot, light intensity is measured for different relative spatial dispositions between the endoscope 46 and the teeth 26. Typically, the derivative of the intensity over time will be made, and the relative spatial disposition(s) between the endoscope 46 and the teeth 26 wherein the derivative equals zero can be used to generate data that is used in conjunction with the relative spatial dispositions between the endoscope 26 and the teeth 26 to determine surface topography of the teeth. As pointed out above, as a result of use of the mirror with aperture 40, the incident light forms a light disk on the surface when out of focus and a sharply-focused light spot only when in focus. Consequently, the distance derivative will exhibit a larger change in magnitude when approaching an in-focus position, thus increasing accuracy of the measurement.

The light reflected from each of the illuminated spots 52 includes a beam travelling initially in the Z-axis in the opposite direction of the optical path traveled by the incident light beams. Each returned light beam 54 corresponds to one of the incident light beams 36. Given the asymmetrical properties of mirror 40, the returned light beams 54 are reflected in the direction of a detection assembly 60. The detection assembly 60 includes a polarizer 62 that has a plane of preferred polarization oriented normal to the polarization plane of polarizer 32. The returned polarized light beam 54 pass through imaging optics 64, typically a lens or a plurality of lenses, and then through an array of pinholes 66. Each returned light beam 54 passes at least partially through a respective pinhole of the array of pinholes 66. A sensor array 68, which can be a charge-coupled device (CCD) or any other suitable image sensor, includes a matrix of sensing elements. In many embodiments, each sensing element represents a pixel of the image and each sensing element corresponds to one pinhole in the array 66.

The sensor array 68 is connected to an image-capturing module 80 of the processor unit 24. The light intensity measured by each of the sensing elements of the sensor array 68 is analyzed, in a manner described below, by the processor 24. Although the optical device 22 is depicted in FIGS. 1A and 1B as measuring light intensity, the device 22 can also be configured to measure other suitable characteristics (e.g., wavelength, polarization, phase shift, interference, dispersion), as previously described herein. In many embodiments, the plane of the sensor array 68 is orthogonal to the returned light beams 54 (e.g., orthogonal to a direction of propagation of the returned light beams). In some embodiments, the plane of the sensor array 68 is non-orthogonal to the returned light beams 54, as described below.

The optical device 22 includes a control module 70 that controls operation of the semi-conducting laser 28. The control module 70 synchronizes the operation of the image-capturing module 80 with the operation of the laser 28 during acquisition of data representative of the light intensity (or other characteristic) from each of the sensing elements. The intensity data and data of relative spatial dispositions between the endoscope 46 and the teeth 26 are processed by the processor 24 per processing software 82 to obtain data representative of the three-dimensional topography of the external surfaces of the teeth 26. Exemplary embodiments of methods for processing the data of the characteristic and relative spatial disposition data are described below. A resulting three-dimensional representation of the measured structure can be displayed on a display 84 and manipulated for viewing (e.g., viewing from different angles, zooming-in or out) by a user control module 85 (typically a computer keyboard). In addition, the data representative of the surface topography can be transmitted through an appropriate data port such as, for example, a modem 88 or any suitable communication network (e.g., a telephone network, the internet) to a recipient (e.g., to an off-site CAD/CAM apparatus).

By capturing relative distance data between the endoscope 46 and the structure being measured for different relative spatial dispositions between the endoscope 46 and the structure (e.g., in the case of a teeth segment, from the buccal direction, lingual direction and/or optionally from above the teeth), an accurate three-dimensional representation of the structure can be generated. The three-dimensional data and/or the resulting three-dimensional representation can be used to create a virtual model of the three-dimensional structure in a computerized environment and/or a physical model fabricated in any suitable fashion (e.g., via a computer controlled milling machine, a rapid prototyping apparatus such as a stereolithography apparatus or 3D printing apparatus).

Referring now to FIGS. 2A and 2B, a probing member 90 is illustrated in accordance with many embodiments. In many embodiments, the probing member 90 forms at least a portion of the endoscope 46. The probing member 90 can be made of a light transmissive material (e.g., glass, crystal, plastic, etc.) and includes a distal segment 91 and a proximal segment 92, tightly glued together in an optically transmissive manner at 93. A slanted face 94 is covered by a reflective mirror layer 95. A transparent disk 96 (e.g., made of glass, crystal, plastic, or any other suitable transparent material) defining a sensing surface 97 is disposed along the optical path distal to the mirror layer 95 so as to leave an air gap 98 between the transparent disk 96 and the distal segment 91. The transparent disk 96 is fixed in position by a holding structure (not shown). Three light rays 99 are represented schematically. As can be seen, the light rays 99 reflect from the walls of the probing member 90 at an angle in which the walls are totally reflective, reflect from the mirror layer 95, and then propagate through the sensing face 97. While the light rays 99 can be focused external to the probing member 90 with any suitable combination of respective focal lengths, in many embodiments, the light rays 99 are focused on a focusing plane 100 external to the probing member 90. For example, as illustrated in FIG. 2C, which shows an end view III-III of the probing member 90, the light rays 99 are focused to a common focal length, thereby being focused on a focusing plane 100 that is perpendicular to the direction of propagation of the light rays 99 external to the probing member 90 (also referred to herein as the Z-axis). As another example, as illustrated in FIG. 2D, which shows an end view III-III of the probing member 90, the light rays 99 are focused to different focal lengths so as to be focused on a focusing plane 100 that is non-perpendicular to the Z-axis. While two configurations of focal positions are illustrated and described, any suitable configuration of focal positions can be employed.

FIGS. 3A and 3B illustrate an optical probe 200 scanning a structure 202 in a global Cartesian reference frame 204, in accordance with many embodiments. (FIG. 3B shows the cross-sectional view I-I as defined in FIG. 3A). The optical probe 200 can be used with any suitable scanning device or system described herein, such as the optical device 22. A two-dimensional array of incident light beams 206 emanating from the optical probe 200 are arranged in a plurality of rows extending in the X direction, including a first row 208 and a last row 210. Each row of the array of light beams 206 is focused to a respective common focal length along the Z direction, thereby forming a diagonal focal plane 212. The focal lengths of the first row 208 and the last row 210 differ by a predetermined length 214 in the Z direction. The optical probe 200 can be moved relative to the structure 202 to scan the structure 202 with the light beams 206. For example, as depicted in FIG. 3B, the optical probe 200 can be translated in the Y direction from a first position 216 to a second position 218.

In many embodiments, each row in the array of light beams 206 is focused to a different depth along the Z direction so as to produce a focal plane 212 that is not orthogonal to the Z-axis. Therefore, as the optical probe 200 is moved relative to the structure 202, the focal plane 212 of the light beams 206 sweeps through a three-dimensional volume of the structure 202. For example, as the optical probe 200 translates from position 216 to position 218, the focal plane 212 sweeps a three-dimensional volume having a Z depth 214. Accordingly, the optical probe 200 can scan the structure 202 in the Z direction through continuous movement of the optical probe 200 relative to structure 202, while maintaining constant respective focal lengths of the light beams 206. Although FIG. 3B depicts movement of the optical probe 200 in the Y direction, in many embodiments, the optical probe 200 can be moved with six degrees of freedom (e.g., three degrees of freedom in translation and three degrees of freedom in rotation) to a plurality of different relative positions and/or orientations between the optical probe 200 and the structure 202.

The array of light beams 206 can be provided in any suitable configuration. For example, the array of light beams 206 can be focused to any suitable number of different focal lengths relative to the optical probe 200, such as 3, 5, 10, 50, or 100 or more different focal lengths. The focal lengths of the array of light beams 206 can be configured to have any suitable range, such as at least 5 mm, 7.5 mm, or 10 mm or more. The focal lengths of the first row 208 and the last row 210 in the array of light beams 206 can be different by any suitable length, such as by 5 mm or less, 10 mm, 15 mm, or 25 mm or greater. For example, the focal lengths can be different by a length within the range of 5 mm to 25 mm.

The array of light beams 206 can be generated by any system or device suitable for focusing a wavelength component of each of the light beams to a respective focal position (e.g., a diagonal focal plane 212). In many embodiments, one or more optics of the optical device 22 can be used to focus an array of light beams to a plurality of fixed focal positions relative to the probe. For example, suitable embodiments of the optics described herein can be included within the grating or micro lens array 38, focusing optics 42, relay optics 44, optics within the endoscope 46, or suitable combinations thereof. The optics can be configured to be used with telecentric and/or non-telecentric confocal focusing optics.

FIG. 4A illustrates an optical assembly 300 for focusing a plurality of light beams to respective focal positions, in accordance with many embodiments. In the optical assembly 300, an array of light beams 302 emanate from a source array 304 (e.g., a micro lens array), are focused by focusing optics 306, and reflect off a mirror 308 (e.g., a mirror disposed within an endoscopic probing member) to form a focal plane 310. The mirror 308 can be positioned at a 45° angle relative to the optical axis in order to produce an orthogonal focal plane 310.

FIG. 4B illustrates an optical assembly 320 for focusing a plurality of light beams to a diagonal focal plane, in accordance with many embodiments. Similar to the optical assembly 300, the system 320 includes a source array 324 that produces an array of light beams 322, focusing optics 326, and a mirror 328. The mirror 328 is tilted at a suitable angle relative to the optical axis, such as a 30° angle, in order to produce a focal plane 330 that is inclined relative to the scanner 332. The focal plane 330 can be used to scan a three-dimensional structure, such as a tooth 334, using fixed focal positions as described herein.

FIG. 5 illustrates a micro lens array 400 for focusing an array of light beams to a diagonal focal plane, in accordance with many embodiments. The micro lenses (e.g., micro lens elements 402) of micro lens array 400 are arranged in a plurality of rows 404, including a first row 406 and a last row 408. Each row of micro lenses is configured to focus light beams to a different focal length, thereby producing a diagonal focal plane.

FIG. 6A illustrates an optical assembly 500 for focusing a plurality of light beams to a diagonal focal plane, in accordance with many embodiments. The optical assembly 500 includes a tilted source array 502, which can be a micro lens array tilted at a suitable angle relative to the optical axis. The array of light beams 504 produced by the tilted source array 502 passes through focusing optics 506, and reflects off mirror 508 to form a diagonal focal plane 510, suitable for scanning the structure 512 with fixed focal positions as described herein. FIG. 6B illustrates the optical path of returned light beams 514 through the optical assembly 500. The returned light beams 514 reflected from the structure 512 pass back through the focusing optics 506, and are directed by beam splitter 516 onto the sensor array 518. As previously described, the sensor array 518 can include a plurality of sensor elements arranged in a plane. In many embodiments, the sensor array 518 is non-orthogonal relative to the returned light beams 514, such that the plane of sensor elements is tilted relative to the direction of propagation of the returned light beams 514. The plane can be tilted by the same amount as the source array 502 in order to allow for confocal sensing of the returned light beams 502.

FIG. 7A illustrates an optical assembly 600 for focusing a plurality of light beams to a diagonal focal plane, in accordance with many embodiments. FIG. 7B illustrates an unfolded configuration of the optical assembly 600. In the optical assembly 600, an array of light beams 604 emanating from a source array 602 pass through focusing optics 606. A non-symmetric optics 608 is disposed between the focusing optics 606 and a mirror 610 and configured to focus the light beams to a diagonal focal plane 612 suitable for scanning the structure 614 with fixed focal positions as described herein. Any suitable optical element or combination of optical elements can be used for the non-symmetric optics 608. For example, the non-symmetric optics 608 can include an off-axis lens tilted at a suitable angle relative to the optical axis. Alternatively or in combination, the non-symmetric optics 608 can include a Fresnel lens including a plurality of segments configured to refract each of the plurality of light beams to a respective focal position in order to produce a suitable diagonal focal plane.

The global surface topography of the structure can be reconstructed by spatially aligning the local intensity data to each other. In many embodiments, the relative position and/or orientation between the optical probe and the structure during the scanning procedure is used to determine the spatial relationships between the intensity data and thereby align the data. Any suitable method or combination of methods can be used to track the position and/or orientation of the optical probe or a suitable portion of the optical probe (e.g., the scanning tip of the endoscope 46 or probing member 90) relative to the structure, such as a suitable motion estimation or motion tracking method. For example, one or more motion tracking devices can be used to generate motion data suitable for determining the position and/or orientation of the optical probe relative to the three-dimensional structure.

In many embodiments, an optical tracking method is used to determine the spatial disposition of the probe relative to the structure with respect to six degrees of freedom. For example, the motion tracking device can include an external camera (or any other suitable image sensor) to generate image data of the probe as it is moved between a plurality of different positions and/or orientations during the scanning procedure. The camera can capture images of any suitable portion of the probe, such as a portion positioned outside of the patient's intraoral cavity. Alternatively or in combination, the camera can capture images of one or more suitable markers (e.g., included in motion tracking element 47) placed on one or more suitable portions of the probe. The images can be processed to estimate the position and/or orientation of the probe relative to the structure using any suitable machine vision method (e.g., a structure from motion algorithm, a photogrammetric method, an image registration/alignment method, and/or an optical flow estimation method such as a Lucas-Kanade method). Optionally, a camera can be integrated into or coupled with the probe, such that image data captured by the camera can be analyzed using a suitable ego-motion estimation method, such as the machine vision methods described herein, to determine the position and/or orientation of the probe relative to the structure.

Alternatively or in combination, the motion tracking device can utilize inertial-based estimation methods to determine the relative position and/or orientation of the probe. For example, the motion sensor can include an inertial measurement unit, such as an inertial sensor. The inertial sensor can be a micro electromechanical system (MEMS) device. In many embodiments, the inertial sensor includes a plurality of accelerometers and/or a plurality of gyroscopes configured to detect motion of the probe with respect to three degrees of translation and/or three degrees of rotation.

In another example, an electromagnetic tracking (EMT) system can be used to track the position and/or orientation of the probe relative to the structure. For instance, an EMT field can be provided by a suitable generator or transmitter, and the position and/or orientation of an EMT sensor within the field (e.g., with respect to up to three degrees of freedom in rotation and three degrees of freedom in translation) can be determined based on the electromagnetic signals detected by the sensor. Any suitable number and configuration of EMT field generators and EMT sensors can be used. For example, an EMT field generator can be situated at a fixed location at the site of the scanning procedure (e.g., coupled to an operating table or patient chair) and an EMT sensor can be disposed on the probe (e.g., included in motion tracking element 47) to track the motion of the probe. In many embodiments, EMT sensors are also be placed on or near the three-dimensional structure (e.g., on a patient's head, face, jaw, and/or teeth) in order to account for any motion of the structure during the measurement procedure. Alternatively or in combination, the EMT field generator can be placed on the structure and used to track the relative motion of a probe having a coupled EMT sensor. Conversely, the EMT field generator can be located on the probe and the EMT sensor can be located on the structure.

Any suitable method can be used to process the motion data to determine the position and/or orientation of the probe relative to the structure. For example, the data can be processed using a motion tracking algorithm combined with a Kalman filter. Optionally, the processing can utilize motion data received from a plurality of the different types of motion tracking systems and devices described herein.

FIG. 8 is a simplified block diagram depicting acts of a method 700 for measuring surface topography of a three-dimensional structure, in accordance with many embodiments. Any suitable optical devices or systems, such as the embodiments described herein, can be used to practice the method 700.

In act 710, a plurality of incident light beams is generated. In many embodiments, the optical device 22 can be used to form a two-dimensional pattern of light beams as described herein.

In act 720, each of the plurality of incident light beams is focused to a respective focal position relative to an optical probe. Any suitable focusing mechanism can be used, such as the embodiments described herein. In many embodiments, the light beams are focused to form a diagonal focal plane to provide Z scanning with motion of the probe, as previously described herein.

In act 730, a three-dimensional structure is illuminated with the incident light beams for a plurality of relative positions and/or orientations between the probe and the structure. In many embodiments, the light beams are focused to a diagonal focal plane such that movement of the probe through a plurality of positions and/or orientations relative to the structure enables three-dimensional scanning of the structure, as described herein. A plurality of returning light beams are produced by illuminating the structure with the incident light beams, with each returning light beam corresponding to an incident light beam.

In act 740, a characteristic of each of a plurality of light beams returning from the three-dimensional structure is measured. As previously mentioned, the characteristic can be any suitable measurable parameter of the light beams, such as intensity, wavelength, polarization, phase shift, interference, or dispersion. Any suitable device configured to measure the characteristic of each of the light beams can be used. For example, a suitable detector unit, such as a sensor (e.g., sensory array 68) including a two-dimensional array of sensor elements can be used, as previously described herein. The sensor array can be orthogonal or non-orthogonal to the returning light beams, based on the configuration of the focusing optics and the light source array.

In act 750, the measured characteristic and the corresponding relative positions and/or orientations between the optical probe and the structure are processed (e.g., by processor 24) to generate surface topography data for the structure. Any suitable method for processing the data of the measured characteristic can be used, such as the embodiments described herein. In many embodiments, the data of the measured characteristic is aligned based on data obtained by tracking the relative position and/or orientation of the optical probe (e.g., motion data and/or image data) as described herein.

In act 760, surface topography for the three-dimensional structure is generated, such as by the processor 24 as described herein. The resultant three-dimensional representation of the structure can be used for any suitable application, such as the dental and orthodontic procedures described herein.

While preferred embodiments of the present invention have been shown and described herein, it will be obvious to those skilled in the art that such embodiments are provided by way of example only. Numerous variations, changes, and substitutions will now occur to those skilled in the art without departing from the invention. It should be understood that various alternatives to the embodiments of the invention described herein may be employed in practicing the invention. It is intended that the following claims define the scope of the invention and that methods and structures within the scope of these claims and their equivalents be covered thereby. 

1. (canceled)
 2. An apparatus for measuring surface topography of a three-dimensional structure, the apparatus comprising: an optical probe; a light source configured to generate a plurality of incident light beams; a focusing optics configured to focus each of the incident light beams through the optical probe and to respective a focal plane relative to the optical probe, the focal plane being fixed relative to the optical probe during surface topology measurement; a light sensor configured to measure a characteristic of each of a plurality of returned light beams that are generated by illuminating the three-dimensional structure with the plurality of incident light beams; a motion tracking device configured to collect motion data during measurement of the characteristic of each of the plurality of returned light beams; and a processing unit comprising instructions executable by the processing unit to determine surface topography of the three-dimensional structure based on the measured characteristic of each of the plurality of returned light beams and the motion data.
 3. The apparatus of claim 2, wherein the characteristic is intensity.
 4. The apparatus of claim 2, wherein the light sensor comprises a two-dimensional array of sensor elements, each sensor element of the two-dimensional array of sensor elements being configured to measure the characteristic from a corresponding returned light beam of the plurality of returned light beams.
 5. The apparatus of claim 4, wherein the focusing optics is configured to form a two-dimensional pattern of the plurality of incident light beams from light generated by the light source, the two-dimensional pattern of the plurality of incident light beams corresponding to the plurality of returned light beams measured by the two-dimensional array of sensor elements.
 6. The apparatus of claim 5, further comprising an optics expander unit configured to expand light generated by the illumination unit to form the two-dimensional pattern of the plurality of incident light beams.
 7. The apparatus of claim 4, wherein the light source is configured to produce a two-dimensional pattern of the plurality of incident light beams corresponding to the plurality of returned light beams measured by the two-dimensional array of sensor elements.
 8. The apparatus of claim 2, wherein the motion tracking device generates a motion tracking signal in response to movement of the optical probe.
 9. The apparatus of claim 2, wherein the focal plane is located between 5 mm and 25 mm from the optical probe.
 10. The apparatus of claim 2, wherein the two-dimensional array of sensor elements is arranged in a plane that is oriented for confocal sensing of the plurality of returned light beams relative to focal lengths of the plurality of incident light beams.
 11. The apparatus of claim 10, wherein the plane of the two-dimensional array of sensor elements is non-orthogonal to the plurality of returned light beams.
 12. A method for measuring surface topography of a three-dimensional structure with a hand-held probe, the method comprising: generating a plurality of incident light beams; focusing the plurality of incident light beams to a focal plane relative to the hand-held probe; measuring a characteristic of each of a plurality of returned light beams that are generated by illuminating the three-dimensional structure with the plurality of incident light beams; collecting motion data corresponding to movement of the hand-held probe during the measuring of the characteristic of each of the plurality of returned light beams; and determining surface topography of the three-dimensional structure based on the measured characteristic of each of the plurality of returned light beams and the motion data.
 13. The method of claim 12, wherein the characteristic is intensity.
 14. The method of claim 12, comprising generating a motion tracking signal in response to movement of the hand-held probe.
 15. The method of claim 12, wherein the focal plane is at a location between 5 mm and 25 mm from the hand-held probe.
 16. The method of claim 12, wherein the measuring is performed using a two-dimensional array of sensor elements, each sensor element of the two-dimensional array of sensor elements being configured to measure the characteristic from a corresponding returned light beam of the plurality of returned light beams.
 17. The method of claim 16, wherein the plurality of incident light beams are generated as a two-dimensional pattern, and the two-dimensional pattern of the plurality of incident light beams corresponds to the plurality of returned light beams measured by the two-dimensional array of sensor elements.
 18. The method of claim 12, wherein the motion data is inertial measurement data.
 19. The method of claim 12, wherein the motion data includes three degrees of translation and three degrees of rotation.
 20. The method of claim 12, further comprising generating a virtual model of the three-dimensional structure based on the surface topography of the three-dimensional structure.
 21. The method of claim 12, wherein the characteristic further comprises wavelength. 